CN106793969A - The device of the sweat volume with the reduction between sensor and sweat gland - Google Patents
The device of the sweat volume with the reduction between sensor and sweat gland Download PDFInfo
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- A61—MEDICAL OR VETERINARY SCIENCE; HYGIENE
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- A61B10/00—Other methods or instruments for diagnosis, e.g. instruments for taking a cell sample, for biopsy, for vaccination diagnosis; Sex determination; Ovulation-period determination; Throat striking implements
- A61B10/0045—Devices for taking samples of body liquids
- A61B10/0064—Devices for taking samples of body liquids for taking sweat or sebum samples
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- A—HUMAN NECESSITIES
- A61—MEDICAL OR VETERINARY SCIENCE; HYGIENE
- A61B—DIAGNOSIS; SURGERY; IDENTIFICATION
- A61B5/00—Measuring for diagnostic purposes; Identification of persons
- A61B5/05—Detecting, measuring or recording for diagnosis by means of electric currents or magnetic fields; Measuring using microwaves or radio waves
- A61B5/053—Measuring electrical impedance or conductance of a portion of the body
- A61B5/0531—Measuring skin impedance
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- A61B5/00—Measuring for diagnostic purposes; Identification of persons
- A61B5/145—Measuring characteristics of blood in vivo, e.g. gas concentration, pH value; Measuring characteristics of body fluids or tissues, e.g. interstitial fluid, cerebral tissue
- A61B5/14507—Measuring characteristics of blood in vivo, e.g. gas concentration, pH value; Measuring characteristics of body fluids or tissues, e.g. interstitial fluid, cerebral tissue specially adapted for measuring characteristics of body fluids other than blood
- A61B5/14517—Measuring characteristics of blood in vivo, e.g. gas concentration, pH value; Measuring characteristics of body fluids or tissues, e.g. interstitial fluid, cerebral tissue specially adapted for measuring characteristics of body fluids other than blood for sweat
- A61B5/14521—Measuring characteristics of blood in vivo, e.g. gas concentration, pH value; Measuring characteristics of body fluids or tissues, e.g. interstitial fluid, cerebral tissue specially adapted for measuring characteristics of body fluids other than blood for sweat using means for promoting sweat production, e.g. heating the skin
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- A61B5/42—Detecting, measuring or recording for evaluating the gastrointestinal, the endocrine or the exocrine systems
- A61B5/4261—Evaluating exocrine secretion production
- A61B5/4266—Evaluating exocrine secretion production sweat secretion
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- A61B5/6801—Arrangements of detecting, measuring or recording means, e.g. sensors, in relation to patient specially adapted to be attached to or worn on the body surface
- A61B5/683—Means for maintaining contact with the body
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- A61B5/6833—Adhesive patches
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Abstract
Perspiration sensor device (400c) for sensing sweat on skin (12), including:One or more perspiration sensors (420) and volume reduce part, when described device (400c) is located on the skin (12), the volume reduces the path (480) that part provides volume reduction for the sweat between the sweat gland on one or more sensors (420) and the skin (12).The volume reduces part can include that volume reduces material (470) and pressure permeation part (460), sweat soluble material (490), the mechanical compliant materials (570) for complying with the skin (12), the adhesive in the sweat path with perpendicular magnetic anisotropy, the microcapsules (1385) including barrier material.The presence that volume reduces part reduces the sweat volume and reduces the sampling interval.
Description
Cross-Reference to Related Applications
The application is related to the 62/003,675th, 62/003,715, No. 62/003,692 U.S. submitted on May 28th, 2014
Provisional application, the 62/074th, No. 295 U.S. Provisional Application that on November 3rd, 2014 submits to submits the 62/th on 2 11st, 2015
114, No. 835 U.S. Provisional Applications, and 62/141, No. 327 U.S. Provisional Applications of the patent No. that on April 1st, 2015 submits to, it is public
Content is opened to be incorporated herein by reference in their entirety.
Background technology
Sweat detection technology is good for for having act several from sports to neonate, to pharmacology monitoring, to individual digital
The huge potentiality of the range of application of health.Sweat contains identical biomarker, chemicals many and carry in blood
Matter or solute, and important information can be provided so that in addition can be diagnosed the illness prior to any sign, health status,
Toxin, performance and other physiological attributes.Furthermore, it is possible to measure sweat in itself, in the behavior and skin of perspiration, skin nearby or skin
Other parameters, attribute, solute or feature under skin, further to disclose physiologic information.
If sweat has so significant potentiality as the example of sensing, then why for cystic fibrosis
It does not occur also after use as long as many decades of baby's chloride determination or illicit drug monitoring pasterIn the sweat of many decades
Liquid inductance is surveyed in document, and most of medical literatures are using rough, slow and inconvenient sweat stimulation, sample collection, sample is defeated
It is sent to laboratory and then by desktop machine and the process of the analysis expert sample of specialty.This process in the extreme labour intensive,
It is complicated and expensive, therefore in most cases, people draw blood not as implementing, because it is the high-performance life of most of forms
The golden standard of thing mark sensing.Therefore, sweat sensing does not give full play to the maximum potential and ability of its biological sensing also,
For biological sensing that is continuous or repeating or monitoring.Additionally, sensing the " Holy grail of such as glucose using sweat
The trial of (holy grails) " not yet successfully produces feasible commercial product, public's perception of the sweat sensing for reducing
With chance space.
In all other physiological fluid (such as blood, urine, saliva, tears) for biological monitoring, sweat can be with
Say it is the sampling rate with maximum variable, because its collection method and variable generation speed result in effective sampling rate
Very big difference.Sweat is also exposed to numerous pollution sources, and it may make effective sampling rate or concentration distortion.Variable sampling
Speed generates the challenge provided in terms of sequential guarantee (chronological assurance), outstanding in continuous monitoring application
Its is such.
For example, it is contemplated that the difficulty of sweat of being sampled in the sweat sensing patch with big sweat volume, the wherein sweat
The sweat and the new sweat for producing that sensing patch may have been produced previously mix, and be intended to measurement be the new generation sweat,
To represent the measured value of the sweat solute of real-time or near real-time.In the presence of the technology for reducing sweat volume, for example, simply make mark
Quasi- sensor is closer to skin, even if in this way, sweat volume is not completely eliminated yet.Additionally, the space between sweat gland includes
Skin surface, it is not the source of sweat, therefore to sweat sensing is without contribution and is worth.Additionally, skin surface can pass through
Microorganism on skin, by dead skin cells biomarker, by the pollutant on skin or in skin or by from body
Cause the pollution of sweat signal to the pollutant diffusion of skin surface.
The conventional method for solving the above problems is included in frequent those reported in clinical literature, for example, be may pass through with sweat
Petroleum jelly cream or oily coating skin.However, these technologies are only verified for sweat collection, be not with it is wearable
Sensor is substantially compatible.For example, petroleum jelly cream understands wetness sensors and is effectively sealed against and isolates with any sweat.
Additionally, not being that other the possible sweat pressure activation technologies being made up of gel or liquid must in some way adhere to skin
On, the strategy of adhesion is that laterally limitation sweat (so that it will not spread to whole skin surface, can not possibly otherwise carry out sweat
Pressure activation).Conventional method cannot be used for wearable sensors, it is necessary to the step of creativeness is realized.Obviously, prior art
Lack the appropriate invention for reducing the volume between sensor and skin in invention.Reduce sweat volume for the quick sampling time or
Sampling time with low-down rate of perspiration is crucial, and the stimulation (that is, wherein needing less stimulation) for extending
Be also likely to be crucial for improving biomarker measured value because for many biomarkers, it is necessary to it is low go out
Sweat rate, the biomarker concentration in sweat is matched with the biomarker concentration found in blood.
Above-mentioned many shortcomings and limitation can be solved in the following manner, i.e., by invention chemical substance, material, sensing
The novel and advanced interaction of device, electronic device, microfluid, algorithm, calculating, software, system and other features or design,
The interaction economy, effective, convenient, intelligence reliably make sweat detection technology just closely be connect with it when sweat is produced
Closely.Using this new invention, sweat sensing can turn into as the noticeable new example of biological sensing platform.
The content of the invention
The present invention provides the sensor device of the volume that can have the reduction between sensor and sweat gland, the body of the reduction
Product reduces the sampling interval.In one embodiment, one is included for sensing the perspiration sensor device of sweat on skin
Individual or multiple perspiration sensors and volume reduce part, and when described device is located on the skin, the volume reduces part
The path of volume reduction is provided for the sweat between the sweat gland on one or more sensors and the skin.The volume subtracts
Widget can be including volume reduction material and pressure permeation part, sweat soluble material, for complying with the skin surface
Mechanical compliant materials, the adhesive in the sweat path with perpendicular magnetic anisotropy, the microcapsules including barrier material and its group
Close.
In one embodiment, perspiration sensor device includes one or more perspiration sensors and volume reduction portion
Part, when described device is located on the skin, it is in one or more sensors and the skin that the volume reduces part
On sweat gland between sweat provide volume reduce path.The path that the volume reduces is included for sweat through described
The predetermined path of sensor.One or more sensors have the sampling interval when sweat is sensed, and the volume reduces
Path reduce sampling interval of one or more of sensors.
In one embodiment, perspiration sensor device includes one or more perspiration sensors and volume reduction portion
Part, when described device is located on the skin, it is in one or more sensors and the skin that the volume reduces part
On sweat gland between sweat provide volume reduce path.Sweat wet material coating is in one or more perspiration sensors
On.
In one embodiment, perspiration sensor device includes one or more perspiration sensors and volume reduction portion
Part, when described device is located on the skin, it is between one or more sensors and sweat gland that the volume reduces part
Sweat provide volume reduce path.The volume reduces part includes multiple closed volumes.
Brief description of the drawings
According to following detailed description and drawings, objects and advantages of the present invention are will be further understood that, wherein:
Fig. 1 is at least one of sectional view of wearable device for sweat biological sensing or paster;
Fig. 2 is at least one of sectional view of wearable device for sweat biological sensing or paster;
Fig. 3 is at least one of sectional view of wearable device for sweat biological sensing or paster;
Fig. 4 A are at least one of sectional views of traditional wearable device for sweat biological sensing or paster;
Fig. 4 B-4D are at least one of sectional views of the device of various implementation methods of the invention;
Fig. 4 E and 4F are at least one of sectional views of the device of numerous embodiments of the invention, it illustrates
Alternative construction;
Fig. 5 is at least one of sectional view of a device for implementation method including bead of the invention;
Fig. 6 A are of the invention including one layer of at least one of section view of the device of bead implementation method
Figure;
Fig. 6 B are at least one of section views of a device for implementation method including two-layer bead of the invention
Figure;
Fig. 6 C are the enlarged drawings of the part 6C for irising out of the device of Fig. 6 B;
Fig. 7 is at least one of sectional view of traditional wearable sweat sensing device further or paster, it illustrates various
Solute path;
Fig. 8 is at least one of sectional view of the device of an implementation method of the invention;
Fig. 9 is at least one of sectional view of the device of an implementation method of the invention;
Fig. 9 A are the enlarged drawings of a part for the device of Fig. 9;
Figure 10 and 11 is at least one of of the device of the different embodiments that can stimulate sweat of the invention
Sectional view;
Figure 12 is at least one of sectional view of the device of an implementation method of the invention;
Figure 13 A are the sectional views of the device of an implementation method of the invention;
Figure 13 B are sectional view of the device of Figure 13 A after it is placed on skin;
Figure 14 and 15 is at least one of sectional view of the device of different embodiments of the invention;
Figure 16 is at least one of top view of the device of an implementation method of the invention;
Figure 16 A are the enlarged drawings of the part 16A for irising out of the device of Figure 16;
Figure 17 is the sectional view of the device of an implementation method of the invention;
Figure 17 A are the enlarged drawings of a part for the device of Figure 17.
Specific embodiment
Definition
As it is used herein, " continuous monitoring " refers to device providing by the continuous or multiple collection and sense to measured value
The measured value of sweat at least one times surveyed and determine, or the ability of multiple sweat measured value over time is provided.
As it is used herein, " when along ensure (chronological assurance) " being directed to can be to from body
New solute or the speed of measurement made of new sweat for.Sequential ensures to include the influence to sensor function
It is determined that, to the previous sweat for producing, the solute for previously producing, other fluids or to the potential of other measurement pollution sources of measured value
The determination of the influence of pollution.
As it is used herein, " it is determined that " more specifically implication can be covered, including but not limited to:Before use device
Predetermined project;In the project for determining during use of device;It can be the determination carried out before and during equipment is used
The project of combination.
As used herein, " sweat sampling rate " is derived from new sweat or sweat the solute arrival of sweat gland or skin or tissue
The effective speed of the sensor of the property of measurement sweat or its solute.In some cases, sweat sampling rate can much compare
Only sweat produces speed more complicated.Sweat sampling rate directly determines that sequential ensures, or is to determine rising for sequential guarantee
The factor of effect.Time and speed are (speed have at least part of unit of 1/s) being inversely proportional, therefore refill sweat body
Product needs the short or few time to could also say that with quick or high sweat sampling rate.The inverse (1/ of sweat sampling rate
S) can also be construed to " sweat sampling interval " (s).Sweat sampling rate or interval are not necessarily rule, discrete, cycle
Property, it is discontinuous, or be restricted.Ensure similar to sequential, sweat sampling rate may also include to previous generation
Sweat, previously produce solute, other fluids or to measured value other measurement pollution sources potential pollution influence determination.
Sweat sampling rate can also whole or in part by solute produce, conveying, fluid convection conveying, the diffusion transport of solute or its
Its factor is determined that the other factors influence new sweat or sweat solute to reach the speed of sensor and/or by old sweat
Or solute or other pollution sources change.The sensor response time is likely to influence sampling rate.
As it is used herein, " sweat stimulation " is directly or indirectly to cause sweat to produce by any outside stimulus, should
Outside stimulus are applied for the purpose for stimulating sweat.The example that sweat stimulates is using such as PILO
Sweat stimulant.It is when being jogged for the purpose of sweat to stimulate, to go to jog and stimulate sweat to be pierced for sweat only in jogging for object
Swash.
As it is used herein, " sweat generation speed " is the speed that sweat is produced by sweat gland itself.Sweat produces speed
Generally measured in units of nL/min/ sweat glands by the flow velocity from each sweat gland.In some cases, then measurement result is multiplied
With from its sample sweat sweat gland quantity.
As it is used herein, " measurement " can mean accurate or accurate quantitative measurement, and can include wider
Implication, for example measure a certain purpose relative variation.Measurement can also mean the measurement of two condition, such as "Yes" or "No" type
Measurement.
As it is used herein, " sweat volume " can be the fluid volume in the space that various ways are limited.Sweat body
Product can be present in sensor and sweat produce point between volume, or from body or from other sources into and out
The volume of the solute of sweat.Sweat volume can include the volume that can be occupied by the sweat between following:Sampling unit on skin
Between sensor on position and skin, wherein sensor does not have intermediate layer, material or part at it between skin;Or on skin
Sampling sites and skin on sensor between, wherein there is one or many between sampling sites on sensor and skin
Individual layer, material or part.
As it is used herein, " solute generation speed " be solute from body or other sources move to sweat in speed
Rate." solute sampling rate " includes that these solutes reach the speed of one or more sensors.
As it is used herein, " microfluidic components " are known in polymer, yarn fabric, paper or microfluidic field being used for
Passage in the movement for guiding fluid or other parts for accommodating fluid at least in part.
As it is used herein, " lossless liquid status " be wherein can by sweat moistening, the space filling or be partially filled with or
Material or surface are in it completely or substantially (for example>50%) dry or the state without sweat.
As used herein, " convection current conveying " be mass motion due to fluid and by fluid carry out to material or preserve special
The conveyer mechanism of property.
As it is used herein, " diffusion " is net movement of the material from area with high mercury to low concentration region.This is also claimed
It is material along the motion of concentration gradient.
As it is used herein, " transmission " be the group or aggregation of the molecule in fluid and rheological body by convection current or
The collective motion of the coordination by spreading or passing through a combination of both.
As it is used herein, " path that volume reduces " is to have passed through added material, device, layer or other external things
Matter and the sweat volume that reduces, therefore it produce the sweat sampling interval that be increased under speed in given sweat.The term exists
Can also be with " the sweat path of reduction " used interchangeably under certain situation, " the sweat path of reduction " is eccrine sweat gland and sensor
Between path, it has reduction in terms of volume or in terms of the surface moistened along path by sweat.Volume reduce path or
The sweat path of reduction includes the path produced by sealing skin surface, because the water in skin-absorbable or exchange sweat
And solute, this can increase the sweat sampling interval and/or cause pollution, and this can also change accuracy or sweat sampling interval
Duration.
As it is used herein, " volume reduction part " refers to the part of any reduction sweat volume.In some cases,
It is not only that volume reduces material that volume reduces part, because volume reduces material and may not allow appropriate apparatus function in itself
(for example, volume reduces material to need to isolate with sensor, because volume reduces material and may damage or degenerate, therefore volume subtracts
Widget may include that volume reduces material and at least one additional materials or layer, by volume reduce material and the sensor every
From).
As it is used herein, " pressure permeation part " is to need pressure with by the part of sweat saturation.Pressure permeation portion
Part can also include by pressure open it is all known to check valve, including known to the technical staff of microfluidic field that
A bit.Sweat can be inaccessible using pressure.In an example, antiperspirant prevents sweat using pressure.Therefore, pressure permeation portion
Part can be designed to be worked under the low pressure being associated with low rate of perspiration.
As it is used herein, " laterally limiting part " is not allow fluid substantially along skin surface deflection dispersion
Part.
As it is used herein, " curable fluids or gel " is fluid or gel of the dry or chemosetting into solid.
In order to understand appropriate numerical value or the expression of sweat sampling rate, and therefore understands that sequential ensures, it should be understood that sweat
Liquid produces speed and sweat volume.Enliven the quantity of the sweat gland difference between different people very big, but between different zones
Compare (for example armpit is compared with groin) and show that (some regions always enliven sweat to identical directional change with more
Gland, and sweat gland is always enlivened in other regions with less).For the different zones of body, sweat gland estimative figure every square centimeter
Amount includes:Palm about 370 sweat glands every square centimeter;The back of the hand is 200;Forehead is 175, and breast, belly and forearm are 155
It is individual;And back and leg are 60-80.Assuming that using 100/cm2Sweat gland density, radius be 0.55cm (a diameter of 1.1cm)
Sensor will cover about 1cm2Area or about 100 sweat glands.Now, it is considered to books:" dermatology:Colour diagram study course "
Some sweat provided in 5th edition produce speed.The sweat of human body at least 0.5 liter of excretion daily, averagely there is 2,500,000 sweat glands,
Have 1440 minutes daily.To prepuberal children, sweat total amount or sweat produce the value of speed generally relatively low.For 2,500,000
Individual sweat gland, its speed is daily each μ l of sweat gland 0.2 or/0.14nl/min/ sweat glands.This is that average minimum " average " sweat is produced
, there are some possible exceptions when itself perspiring and somewhat increasing (such as measure sleep cycle etc.) in raw speed.Again, root
According to " dermatology:Colour diagram study course " the 5th edition, the maximum quantity of perspiration for producing for each person every day is 10 liters, and its average out to is every daily
Individual sweat gland is 4 μ l, or about 3nL/min/ sweat glands to the maximum.This produces speed high about 20 times than minimum sweat.
According to Buono 1992, J.Derm.Sci.4,33-37, " the eccrine sweat gland in training and untrained male
Cholinergic sensitiveness " maximal stimulation sweat produce speed, by PILO stimulate maximum sweat produce speed pair
It is about 4nL/min/ sweat glands in untrained male, (often taking exercise) male for training is about 8nL/min/ sweat glands.Other
Source shows that the maximum sweat generation speed of adult can be up to 2-4 liters or daily 10-14 liters (10-15g/min per hour
m2), it is based on quantity hourly and is converted into 20nL/min/ sweat glands or 3nL/min/ sweat glands.From K.Sato's and F.Sato
(data are the monkey sweat on extracting and separate to the sweat stimulus data of " pharmacological reaction of isolated single eccrine sweat gland "
Gland, it is closely similar with the sweat gland of the mankind) show there can be the sweat for being up to about 5nL/min/ sweat glands to produce speed by stimulation
Rate, and disclose the sweat excitor substance of several types.For simplicity, we can assume that the description below is with this hair
Used in calculating in bright (but being not used in the limitation present invention):It is averagely for about 0.1nL/min/ sweat glands that minimum sweat produces speed,
And it is for about 5nL/min/ sweat glands that maximum sweat produces speed, difference is about 50 times between the two.
Based on 100/cm2It is sweat gland density it is assumed that radius can be covered about for the sensor of 0.55cm (a diameter of 1.1cm)
1cm2Area or about 100 sweat glands.Next, assume below the sensor towards skin sweat volume (sensor and
Space between skin) there are 50 μm or 50 × 10-4The average height and identical 1cm of cm2Area, its provide about 50 ×
10-4The sweat volume of cm or 50E-4mL or 5 μ L volumes.Speed and 100 sweat glands are produced in the maximum sweat of 5nL/min/ sweat glands
In the case of, it is necessary to update sweat volume completely in 10 minutes (using only the first principle/simplest calculating).In 0.1nL/
In the case that the minimum sweat of min/ sweat glands produces speed and 100 sweat glands, then need come fully more within 500 minutes or 8 hours
New sweat volume.If sweat volume can substantially reduce 10 times to 5 microns of volume height, minimum and maximum time difference
It is 1 minute and 1 hour, but minimum time will also be subjected to diffusion and other pollution problems (and 5 μm of dead space volume highly general
It is technical challenge).Time and speed are inversely proportional (at least part of unit that speed has 1/s), therefore refill sweat
Short time needed for volume could also say that with quick or high sweat sampling rate.
Space between sensor and skin can include microfluidic components.For example, covering 1cm225 μ m-thicks of area
Paper or glass fiber sheets are equal to the volume of 2.5 μ L.If paper is 50% porous (50% solid), sweat volume is 1.25 μ
L.In the case where the maximum sweat for 5nL/min/ sweat glands produces speed and 100 sweat glands, it is necessary to 2.5 minutes update completely
Sweat volume.In the case where the minimum sweat of 0.1nL/min/ sweat glands produces speed and 100 sweat glands, it is necessary to about 100 minutes
To update sweat volume completely." updating completely " is the term that should be construed broadly as in some cases, unless provided into one
The details of step or calculating.Due to mixing and diffusion over time, the moment with " fresh sweat volume " must use tool
Body using and equipment and conditions associated more accurate details determine.
In some cases, examples detailed above can be interpreted to provide the sampling interval of sweat, i.e. the sampling interval will substantially
For sweat is filled or time required for refilling space, significantly diffusion, mixed may occur in some cases in the space
Close and pollute.The reality that the sampling interval of sweat can also be broadly interpreted as the those aspects for including the sweat to be measured is defeated
Send, spread or pollution number.Sampling interval can be with widely varied.For example, because small ion may be easier to expand than larger protein
Dissipate, both can be the solute in measurement influence sampling interval.Sampling interval can be extensively varied, for example, designed based on device
Finer aspect, for example wherein sweat always from skin flow forward to sensor and crosses the design of sensor, with
And the somewhere between wherein sensor in contrast and skin there are one or more sweat dead space volumes or sweat stagnates body
Long-pending equipment.Therefore, term " sampling interval " should be interpreted broadly, and will need to be directed to and to measure in some cases
Sweat each aspect based on each case be determined by experiment.
Sweat stimulates or sweat activation can be realized by known method.For example, sweat stimulation can be by simple
Thermostimulation, by oral drugs, by the medicine of intracutaneous injection such as MeCh or PILO, and by using from
These medicines are introduced skin to realize by sub- electric osmose.Device for iontophoresis can for example provide DC current and use
The large-scale lead electrode of porous material is lined with, wherein positive pole is soaked with 2% Pilocarpine hydrochloride, negative pole is with 0.9%
NaCl solution is soaked.Can also be by requiring that the movable or shape for causing them to perspire is carried out or increased using the subject of paster
State is controlled or generates sweat.These technologies can be referred to as producing sweat the active control of speed.
The present invention be at least applied to measurement sweat, sweat produce speed, the guarantee of sweat sequential, its solute, from cutaneous metastatic
Solute in sweat, the material in the characteristic or skin surface of skin surface, the material under characteristic or skin under skin
Any kind of perspiration sensor device.The present invention is applied to sweat sensing device further, the form that it can take include paster,
The form of ring, band, a part for clothes, wearable device or any suitable mechanism, it reliably makes, and sweat stimulates, sweat is received
Collection and/or sweat detection technology when sweat is produced just with its close proximity.Some embodiments of the present invention utilize adhesive
Device is maintained near skin, but device can also be kept by by device against other mechanisms that skin is fixed, for example
In band or the embedded helmet.
Some implementation methods of the invention show the sensor as simple independent component.It should be appreciated that many sensings
Device needs two or more electrodes, reference electrode, or NM additional support technology or feature in description herein.
Sensor is preferably in itself electric, but it is also possible to including optics, chemistry, mechanical or other known biological sensing mechanism.Pass
Sensor can for two, three or more, to provide improved data and reading.Sensor can be sensed by by sensor
Content name, for example:Perspiration sensor;Impedance transducer;Sweat volume sensor;Sweat produces rate sensor;With
Solute produces rate sensor.Some implementation methods of the invention show the sub-portion of the device by sweat sensing device further is turned into
Part, the device has the more subassemblies for apparent (such as the battery) for needing to use in various applications, and is
It is succinct and concentrate on creativeness aspect, it is not explicitly illustrated in figure or describes in embodiments of the present invention.As another
Example, many embodiments of the present invention can utilize wearable device, paster, bandage and other adhere to skin technology or
Mechanism known to the technical staff in the field of material or other devices, skin is firmly-fixed to by the device or subassembly of skin
On skin, or pressure ground continuous contact is kept with skin, or even with skin in uniform convex ridge or groove comply with
(comformal) contact, and including within the spirit of the invention.The application has the explanation based on PCT/US13/35092
Book, the disclosure of which is incorporated herein by reference in their entirety.
With reference to Fig. 1, perspiration sensor device 100 is placed on or near skin 12.In alternate embodiments, sweat is passed
Sensor arrangement can simply be fluidly connected to the region near skin or skin by microfluid or other suitable technologies.Device
Wire communication 152 or radio communication 154 are between 100 and reader device 150.In an embodiment of the invention,
Reader device 150 can be smart phone or portable electric appts.In alternate embodiments, device 100 and reader
Device 150 can be combined.In other optional embodiment, communication 152 or 154 is not lasting, can be in device 100
Simply downloaded from the simple disposable data of device 100 when having completed the measurement of its sweat.
As shown in Fig. 2 from skin 12 be carried to sweat by microfluidic components 230 being placed in impermeable substrate 214
Sensor 220.For example, sensor 220 can be the impedance transducer for cytokine biological mark, impermeable substrate
214 can be polyimide film.Presence or the flow velocity of one or more solute or sweat in the measurement sweat of sensor 220.It is micro-
Fluidic component 230 can be such as paper, polymer microchannel, pipe or gel or sweat is transported into sensor from skin 12
220 other devices.If the small volume of microfluidic components 230, the sweat flow velocity through sensor 220 will be higher, will
The mixing of the fluid collected by the diffusion of pollution abatement solute or previous time.By reducing solute from the previous core for producing
It is drawn to the reverse diffusion of the sweat for crossing sensor 220, there is provided more preferable sequential ensures.For continuous monitoring, microfluid portion
Part 230 can be passed to the hydrogel that sensor 220 reaches continuous absorption with wicking sweat, and the hydrogel is therefore with from skin
The speed for providing sweat pumps out sweat and sweat is passed through sensor from skin 12.
For the example for using of device 200, device can be used for the runner during match, and runner is during competing
Sweat with 5nL/min/ sweat glands produces speed.Microfluidic components can be covering 100 sweat glands or 1cm225 μ m-thicks
Paper or glass fiber sheets, equivalent to 2.5 μ L (25 × 10-4Cm × 1cm × 1cm=25 × 10-4cm3=2.5 × 10-3ML sweat)
Liquid is accumulated.If paper is 50% porous (50% solid), sweat volume is 1.25 μ L.Thus, for example, sweat sampling rate
May be calculated 1.25 μ L/ (sweat glands of 5nL/min/ sweat glands x 100)=2.5min.Therefore, sweat sensing device further 200 can be provided
The sequential of 2.5 minutes ensures, it is meant that the data of the report of device can be interpreted to represent the time window of about 2.5 minutes
At least one physiological measure of the interior runner determined by the sweat for newly producing.This is that single order type is calculated, and it is in some situations
Can be down high precision, such as the situation of the disease for dramatically increasing of specific solute in sweat.It should be noted that the meter
Calculation have ignored because sweat volume increases caused by the factors such as pachylosis.
As shown in figure 3, device 300 includes carrying the material of two or more sensors 320,321 and reference electrode 322
311, there is adhesive 310 below material 311.Volume 340 is between adhesive 310 and skin 12.Adhesive can be pressure
Quick, liquid, stickiness hydrogel, it promotes with the firm electrical contact of skin, fluid is contacted and iontophoresis is contacted.Material
311 for example can be porous for sweat, be similar to hydrogel or yarn fabric ground wicking sweat, or be impermeable for sweat
's.Skin 12 has roughness to it, this figure 3 illustrates.Even if using adhesive 310, in some embodiment party of the invention
In formula, can also there is volume 340, it is combined with effective porous volume or absorbing sweat the liquid product of adhesive 310, it is possible to provide skin
Sweat volume between 12 and sensor 320,321 and electrode 322.Sensor 320 can be selected for measuring the ion of sodium
Property electrode, sensor 321 can be the electrical impedance spectrum sensor for measuring cortisol, and sensor 322 can be nothing
The Ag/AgCl reference electrodes of drift.Sweat generation speed can be carried out by sensor 320 by na concn measurement, and sweat
Producing speed can also be carried out by sensor 321 by impedance measurement, and the sweat that measurement is provided together produces speed.If surveyed
The most accurate impedance measurements of skin are measured, then reference electrode 322 should preferably the Centimeter Level of range sensor 321 be far or more
Far.
For the example for using of equipment 300, equipment 300 can be adhered to (the volume with 50 μm of depth of groove
340 average height can be 25 μm) skin site.If sensor 320 has 10mm2Area, and adhesive 310
Volume it is negligible, then predetermined sweat volume is by least 250nL.According to the pore density based on the placement location on body
Calibration look-up table, 320 lower section average out to of sensor 10 holes will be determined.If it is 1nL/min/ sweat glands that sweat produces speed,
Then effective sweat flow velocity will be 10nL/min, therefore the sweat sampling interval is 25 minutes.If sweat speed is relatively low, such as
0.1nL/min/ sweat glands, then the sampling interval will be the hour order of magnitude.Because this is one relatively slow for some applications
Sampling interval, for certain form of measurement, it may be necessary to include diffusion and other pollution influences.The depth of wrinkle of skin
It can be tens microns, roughness can be more than 10 μm.Skin or device can deform, expand or occur physical geometry
Change.Some skins, expand and reduce sweat flow rate (particularly skin thicker finger tip and pin) as it gets wet.
If sweat volume can be reduced, faster sweat sampling rate can be realized, if for example, the groove of skin can be filled
Certain type of packing material, then sweat sampling rate can double or even more many.
As shown in Figure 4 A, device 400a includes material 430, and it is absorbing sweat material, such as fabric or gel.Device 400a bags
Include at least one sensor 420 and adhesive 410.The position of sweat duct 14 is marked.The He of sensor 420 is also schematically marked
Sweat volume 480 between pipe 14, it represents that new sweat leaves effective volume or the flowing when managing and reaching sensor 420 at it
Path.In the embodiment shown, device 400a does not have sweat volume to reduce part.Calculated using the first principle, Ke Yixiang
Answer ground that sampling volume is calculated as the entrance traffic income with the volume divided by new sweat.Those of ordinary skill in the art will recognize that
To can be calculated in more detail.For example, it is assumed that 140 sweat glands/cm2(such as belly), the sensor of 2.5mm diameters, 15 μm
Sensor and skin gap, and 15 μm due to the effective clearance (30 μm of total effective clearances) of skin roughness.For 0.5
With 5nL/min/ sweat glands, the filling time or sampling interval of the volume were by respectively 40 minutes and 4 minutes.Again, due to sensing
Uneven sweat flow velocity between device 420 and skin 12 and the diffusion due to such as solute and sensor response time because
Element, the actual sampling interval will be slower in practice.The need for this further highlights reduction sweat volume 480.Need not be right
The accurate calculating of sampling interval and sweat volume or prediction reduce sweat volume 480.Conversely, embodiment of the present invention shows
The sweat volume for reducing and the sampling interval for reducing, and the degree for understanding the details that the sampling interval is considered need not be related to.
As shown in Figure 4 B, device 400b includes the feature of Fig. 4.And also reduce part including volume.In shown embodiment party
In formula, volume reduces part includes that pressure permeation part 460 and volume reduce material 470.Device 400b also includes absorbing sweat material
430 and reduce the coplanar adhesive 410 of material 470 with volume.Device 400b includes that sweat stimulus and driving electrodes (are not shown
Go out), the sweat for the axon reflex for urging sweat to sweat stimulates, and the sweat can reach sensor 420.With do not use volume
The situation (for example, the sweat volume 480 in Fig. 4 A) for reducing part is compared, and volume reduces part can reduce sweat volume 480.At this
In implementation method, it is not only that volume reduces material that volume reduces part, because volume reduces material and may not allow to fit in itself
When device function.For example, it can be petroleum jelly cream that volume reduces material 470, if it can in being individually used for device 400b
To be coated in the surface of sensor 420 and cause its inoperable.Volume reduce material 470 preferably with sweat and various
Sweat solute is unmixing.Therefore, by further example, pressure permeation part 460 can be with many of sufficiently small hole
Microporous barrier so that the viscogel of such as petroleum jelly cream will not permeate completely it or will not rapid osmotic it, and viscosity is much lower
Fluid, such as sweat will much more quickly penetrate through pressure permeation part 460.Because pressure permeation part 460 is pressure oozing
Saturating, so sweat only or will can preferentially permeate the part 460 near sudoriferous duct 14 itself.Due to reducing available sweat
Liquid is accumulated, and device 400b can have faster sweat sampling rate.Compared with the implementation method of Fig. 4 A, the embodiment party shown in Fig. 4 B
Sweat volume 480 can be reduced 2 times or more by formula.Sweat volume 480 can also be expressed as in " path that volume reduces ".Skin
What the part in the path that the volume between 12 and pressure permeation part 460 reduces was produced by sweat in the illustrated embodiment
The pressure initiation of itself.At this point, the hydraulic pressure of the sweat from sweat duct 14 allows for fully dislocation volume and reduces material
At least a portion of material 470, the part in the path 480 that volume reduces is formed to reduce in volume in material 470.At one
In implementation method, it is petroleum jelly cream or similar material (i.e. non-solid) that volume reduces material 470 so that sweat can be produced by material
The path of material 470.As an alternative or supplement, in one embodiment, volume reduces material 470 can be included in volume reduction
The hydrophilic wicking fiber or the network of hole (not shown) of a part for sweat volume 480 is formed in material 470.
With reference to Fig. 4 C, device 400c include the feature of Fig. 4 A and Fig. 4 B, optional spacer materia 410 and also including
Sweat soluble material 490.Volume reduction material 470 can be with high viscosity, gellike performance or so that it is difficult to and pressure
The material of other characteristics that power filtration module 460 is coordinated.As an example, volume reduction material 470 can retaining pressure filtration module
Hole in 460, and the pressure that sweat is produced may be insufficient to allow for sweat and be advanced into by pressure permeation component 460.It is this
Difficulty can be solved by adding soluble material 490.As an example, sweat soluble material 490 can by such as sucrose,
The material of salt, polyvinyl alcohol, PEO or any other suitable material is constituted.The presence of sweat soluble material 490
The reduction for reducing the sweat volume that part is provided by volume is enhanced, and the resulting sampling interval is reduced.
Embodiments of the present invention can include that promotion sweat soaks soluble material 490 or sweat is reduced by volume
Feature, surfactant or other side that material 470 soaks pressure permeation part 460.All these technologies are herein
Referred to as sweat moistening promotes feature.As in the embodiment depicted in figure 4c, soluble material 490 can be the micro- folding with burr
Folded film, to promote the wetting and dissolving of sweat.If without surface nonplanar coarse or with burr, even if there is sweat pressure
Power, the impermeable film of sweat that volume reduces material 470 is likely between sweat and soluble material 490 in the presence of than desired
The longer time.However, embodiments of the present invention may include the soluble material 490 on the surface without burr.In example
In property implementation method, soluble material 490 can be coating or film on pressure permeation part 460.In pressure permeation part 460
Be the film with hole implementation method in, soluble material 490 can be the hole of retaining pressure permeable member 460 at least in part
Material.In one aspect of the invention, implementation method can include for example by improving sweat in soluble material 490
Infiltration and/or increased by reducing soluble quality sweat by sweat soluble material 490 rate of dissolution spy
Levy.In one embodiment, soluble material 490 can be many microporous polymers comprising hole or space.In this respect, may be used
The microporosity matter of soluble materials 490 increased the permeability of sweat, and therefore increased rate of dissolution.
In an alternate embodiment, sweat soluble material 490 may include the thing by sweat soluble material 490 is kept
Manage the non-sweat solubility plastic supporting pieces of integrality.Fig. 4 D show device 400d, and wherein sweat soluble material 490 includes
The plastic wire 462 of non-solubility.Show after sweat has dissolved a part of sweat soluble material 490, sweat volume 480
Set up and device 400d when device 400d is measuring sweat.Skilled artisan will realize that, the sweat of other constructions
The reduction and enhancing that soluble material 490 can also strengthen the sweat sampling interval are subtracted by the sweat volume that volume reduces part offer
It is small.
With reference to Fig. 4 E and 4F, a part for the sweat sensing device further of various implementation methods of the invention is illustrate only.
In implementation method shown in Fig. 4 E and 4F, soluble material 490 and volume reduce material 470 and are used with being alternately arranged mode, its
Middle sweat can be based on the dissolving of pressure and/or soluble material 490 and form path so that provide the sweat volume for reducing
480.It will be appreciated by those of ordinary skill in the art that other alternative arrangements are also possible.
With reference to Fig. 5, device 500 includes microfluidic components 530, sensor 520 and carries the impermeable base of sensor 520
Bottom 514.Groove in skin 12 is filled with bead 570.It refers to spheric granules that " bead " is conventional, however, in the present invention " bead "
Implication include allow particle cross any grain type for moving each other and condensing together.Bead 570 can be parent
Water so that they are easily soaked by sweat fluid.Pearl 570 can be adhered into microfluid component 530 before paster is applied,
And when paster 530 is applied, they are moved in the groove in skin when pressure is applied to skin 12.Bead 570 may be used also
To help fill the space above groove.The adhesion of bead 570 and microfluidic components 530 can be by together with holding them in
The Non-Volatile Fluid of viscosity such as the solid dissolved in sweat of sucrose are provided.For the bead 570 of isosphere, most
About 74% volume is used in intensive polymerization.The random polymerization of isosphere typically results in about 64% density.Certainly, the aggregation
There can also be relatively low density.However, it is anticipated that sweat volume can be reduced 30%, 50% by spheroid, even as high as about
60%.Bead can also be inside adhesive, and adhesive and bead flow or comply with (conforming) enough, think that sweat is carried
The path that donor product reduces.
With reference to Fig. 6 A, device 600a includes absorbing material 630 for wicking sweat, at least one sensor 620, optional
Film or net 660, hydrophobic bead 670 and adhesive 610.The path 680 that volume reduces is limited by hydrophobic bead 670, forms body
Product reduces at least a portion of part.For example, bead 670 can be made up of any hydrophobic polymer, or can be by with making
The non-hydrophobic polymer of the hydrophobic shallow layer of bead 670 is made.In one embodiment, bead 670 can be by hydrophobic poly- four
PVF is made.If bead 670 is coated with transferable coating, such as hydrophobic oil or gel, then optional film 660 is protected
Sensor 620 is not influenceed by coating.In this respect, the opening or hole in film or net 660 will be less than beads 670.In bead 670
Do not include that transferable coating and sensor 620 are hydrophilic or are coated with water wetted material (not shown) and are fully soaked with by sweat
In implementation method, film 660 can not be included.Film 660 for example can be the material than preferentially being soaked by sweat with oil phase, therefore right
It is more permeable for sweat.Film 660 and bead 670 can serve as pressure permeation part together.Oil can be from skin 12
Surface.
Skin oil generation over time is also problematic in that.In one aspect of the invention, bead 670 can be
Oiliness (oleoscopic) so that they can absorb oil.Can mitigate skin oil to device 600a's including oiliness bead 670
The influence of function.As an example, bead 670 can by such as by Imbibitive Technologies companies sell English must
The material for thinking commercially to be used in (Imbiber Beads) is constituted.Bead 670 can be the solid powder or solid in many types
Any suitable geometry present in particle.Because oil suction bead absorbs oil, they can expansion.If, when they are swollen
Swollen, bead becomes soft, can assemble it is tighter (as Ying Bisi), then sweat volume can reduce.In addition, or alternately,
The hydrophobicity of bead 670 can also allow the skin oil (that is, lipophilicity) in the space between their absorption beads.
With reference to Fig. 6 B, device 600b includes the feature similar to device 600a, and also including adjacent with hydrophobic bead 670
Bead 672.Bead 672 can be hydrophilic or smaller than the hydrophobicity of bead 670.Bead 672 can also have identical hydrophobic
Property, but causing that they show relatively low laplace pressure to sweat with larger spacing so that they are than infiltration pearl
Grain 670 preferentially permeates sweat.Volume reduces path 680 and is limited by hydrophobic bead 670, and is provided to biography by bead 672
Sensor 620 is fluidly connected.In one embodiment, bead 672 is rigidly constrained so that they are held in place to protect
Sensor 620 is not influenceed by presumable transferable coating on bead 670, similar to optional film or net shown in Fig. 6 A
660.Selectively, in one embodiment, bead 670 is more loosely constrained by wax, grease or other materials so that bead
670 can comply with skin 12.Device 600b can be small area and be fixed by the adhesive around its periphery or use hand
Bracelet, band or other method are clamped to skin.For example, the area of device 600b can be in about 0.3mm2About 3mm2Between.
In one aspect of the invention, hydrophobic bead 670 can be coated with hydrophobic liquid, gel, grease or powder, described
Hydrophobic liquid, gel, grease or powder can be transferred to skin surface, will form hydrophobic coating on skin, skin barrier thing or
Sealant.For example, this transferable hydrophobic coating can be polytetrafluoroethylene (PTFE) drainage powder, the hydrophobic silicone fluid of stickiness,
Petroleum jelly cream or Silica hydrogel.With reference to Fig. 6 C, when device 600b puts on skin, transferable hydrophobic coating 674 can make skin
It is hydrophobic so that skin is sealed or sweat or solute for being conveyed into skin or transfer out from skin are impermeable.At one
In implementation method, the bead 670 of adjacent skin 12 can have a transferable coating 674, and the bead 672 of proximity transducer 620
Can not have coating 674, this will reduce the chance that coating 674 reaches sensor 620 and disturbs the operation of sensor 620.
Wherein in the embodiments of the present invention of device or paster including the bead with the coating that can be transferred to skin,
The equipment for described device or paster to be applied to skin can be included, the equipment applies pressure and is pressed against skin simultaneously with by device
Longitudinal stress is provided or power is transferred on skin with ensuring coating.In one embodiment, it is applied to skin 12 in device
Before upper, bead 670 can rigidly be combined together, to cause that applying is easier.For example, bead 670 can with it is such
Material is combined, and the material allows bead 670 to flow when device is placed on skin and is applied with stimulation.The material can be with example
Wax, other kinds of hydrophobic coating or non-hydrophobic adhesive in this way.Stimulation for example can be heat.The device is applied on skin
This approach improves adhesion from the device to skin.
In one aspect of the invention, and with further reference to Fig. 5, Fig. 6 A and Fig. 6 B, bead 570,670,672 can be by
Magnetic force is combined, and magnetic force allows them to flow under mechanical stress or mobile, but holds them on paster.In an implementation
In mode, bead 570,670,672 is magnetic.The biological compatibility magnetic microballon of many forms, polymer or inorganic matter are
It is well known by persons skilled in the art.In another embodiment, bead 570,670,672 can also be metal or magnetisable
, with external magnetic field (for example, magnetic magnetic conductivity be more than 1, as some metals) so that they bead 570,670,672 with
Device is held at appropriate location before being applied on skin.For example, applicator can include permanent magnet or electromagnet.As another
One example, device collection can be into having magnetizing part, it is necessary to the magnetizing part is with before device is applied on skin securely
All bead is held in place.
The specific advantages of the implementation method shown in Fig. 6 B include following:(1) volume reduces material and the autoregistration of sweat hole;
(2) volume reduces material will not damage sensor operation;And (3) volume reduce material comply with skin and skin surface other
Aspect (for example, roughness, wrinkle, hair, dust fiber etc.), but for incompressible so that what outside or inside induced
The path of volume reduction will not be damaged or be changed to mechanical pressure.For the 3rd advantage, in other words, volume reduces material can be with
It is have porous mechanical compliant member (i.e. bead) to sweat.It will be appreciated by those of ordinary skill in the art that producing these excellent
The alternative materials or construction of point are desired by the present invention.Another favourable aspect of the invention described above is included in the bringing device phase
Between on skin apply hydrophobic encapsulant or barrier coat.In one embodiment, device can be at it towards the side of skin
Use the porous memory foam for being coated with oily or other types of sealant.
As it was previously stated, embodiments of the present invention can include " path that volume reduces " for sweat, it is on subtracting
The small path away from skin, wherein extra pollutant can at the path into skin and change or obscure sweat sensing.
Substantially, skin is in itself permeable, and constitute sweat and sweat solute can also into and out exceptional space,
Therefore total effectively sweat volume is increased in some cases.This low sweat produce and/or flow velocity under it is especially true, wherein molten
It is suitable that diffusion of the matter in sweat or skin actually conveys solute with the convection current in sweat.Therefore, the path that volume reduces should
When the feature and aspect that are construed to include obstruction discussed below or prevent sweat or solute conveying turnover skin, so as to obtain volume
Reduce path to be limited primarily to only above skin.For example, the implementation method shown in Fig. 6 C reduces sweat or its solute turnover skin
The conveying of skin, even if therefore generate the space being also limited under low sweat flow velocity above skin volume reduce path.
With reference to Fig. 7, the routine conveying from skin 12 to the solute of sensor 701 is shown.For convenience's sake, sensor
701 are schematically illustrated as discrete component, but sensor may include various elements.Element 790 schematically shows the He of skin 12
Contact between sensor 701.It will be appreciated by those of ordinary skill in the art that the accurate structural of element 790 or description can become
Change.In one embodiment, element 790 can represent the directly contact between skin 12 and sensor 701.In another reality
Apply in mode, element 790 can represent hydrogel.Solute in skin or sweat by path 752,754 and 756 freely or
Spread at least partially through element 790.On path 754, skin 12 can absorb water or sweat solute, and can leach
Pollute solute of sweat etc..Due to various transport paths, sensor can be received from sweat duct 14 and the surface of skin 12
The signal partially or substantially mixed between solute.These signals may be obscured molten to one or more sweat in some cases
The significant measurement of matter.
With reference to Fig. 8, an embodiment of the invention includes the sensor 801 adjacent with element 890, and element 890 is configured
Into with to turnover skin or skin surface solute or skin surface on pollutant conveying 858 compared with, be more beneficial for turnover
The conveying 856 of the solute of sweat gland or sweat duct.In this respect, " path that volume reduces " and " sweat volume " are derived from including reduction
The volume of the sweat of skin 12, rather than the volume of the sweat from pipe 14.Conveying can by pressure-actuated flowing, ooze
Thoroughly, electro-osmosis, diffusion, electrophoresis or it is suitable for conveying other power of solute in the fluid of such as water.Ordinary skill people
Member is it will be recognized that the improvement of transmission path will change for different solutes and different applications.Element 890 can be included in
The feature or part discussed in other illustrative embodiments.
With reference to Fig. 9, element 905 is conducive to the conveying 956 of sweat or solute in sweat, is unfavorable for solute in skin 12
Or the conveying 958 on skin, this will be discussed in greater detail below.Solute enters the conveying 956 of microfluidic components 930 after
The conveying to sensor 920 is allowed, for sensing solute.In one embodiment, element 910 is for supporting sensor
920 substrate.
With reference to Fig. 9 A, a part for element 905 is shown, it includes adhesive 912, the adhesive 912 can be by element
905 rest substantially against skin 12 seals so that prevent significant horizontal sweat or solute between adhesive 912 and skin 12
Conveying.Because skin is nonplanar, adhesive 912 is soft or flowing, and can be partially or completely
Penetrate into groove on skin surface.Adhesive 912 can be the gel or class pastes of pressure permeation.Adhesive or film
914 can be firmer than adhesive 912.Adhesive or film 914 can be provided so that soft or flowing adhesive 912 is not
The hole in film or net 916 can excessively be penetrated into.It would be recognized by those skilled in the art that the arrangement of optional element 905 and
Part is possible.
In embodiments of the present invention, the part of pressure permeation can be track etching-film.As an example, track is etched
Film can be the film that can be sold from Whatman companies or SPI Scientific.In an illustrative embodiments, Fig. 9 A's
Film 916 is track etching-film.Hole in track etching-film will act as pressure valve, it means that need certain sweat pressure so that
Fluid can be contacted and enter adjacent layer by film 916, such as the microfluidic components 930 shown in Fig. 9.Exist sweat gland and
The position of sweat duct, can realize being contacted with the fluid of skin.
Here is example calculation.Sweat duct may produce up to 500mm mercury column or about 65kN/m2Pressure.Can be by film
The laplace pressure that a hole with diameter d (as shown in Figure 9 A) keeps in 916 can be calculated as below:
Wherein p is pressure, and γ is surface tension, and R is the radius in hole, and the diameter in d holes, θ is the contact of fluid and hole side
Angle.
120 degree of contact angles and similar to water surface tension in the case of, the diameter in the hole needed for bearing perspiration pressure
Can Inversion Calculation as follows:
Result is d=2.15 μm, it is meant that hole needs the diameter more than the diameter, to allow sweat gland pressure to gate by film
916 fluidly connect, but still need sufficiently small so that if fluid profit of other regions of film 916 by above or below
If wet, the degree that will not be drenched or be drenched by fluid by fluid is smaller, because in such part, such pressure is not enough
To activate fluidly connecting by film 916.Assuming that fluid surrounds the edge in hole and reaches the effect of the contact angle of 180 degree,
And/or relatively low sweat pressure, aperture can be even more big.
In an embodiment of the invention, adhesive can be based on hydrogel and for sweat and/or its
Solute is partly permeable.In another embodiment, adhesive dissolves in sweat, and adhesive by means of the electricity for applying
Gesture, is changed and solidified by the ion or pH value of adhesive.For example, the silicon adhesive of many types is pH curable, and
It is also water miscible when uncured.Solidification can be limited to the contact area of skin, because pH value or ion can be restricted to
Only change in the case where can be made electrical contact with skin.In one aspect of the invention, for example using skin iontophoresis in skin
PH gradient is produced to can be used for only partly solidifying adhesive when adhesive contacts (i.e. not on sweat duct) with skin on skin.
When sweat is produced, sweat can dissolve any uncured adhesive and promote sweat to be freely transported to film 916.
Present invention contemplates various constructions of adhesive, the such state of its generation:With outside sweat duct or substantially exist
The conveying of its outside skin area is compared, and the state is more beneficial for the solute at neighbouring sweat duct or above sweat duct
Conveying.In one embodiment, adhesive phase can be patterned as lattice (such as honeycomb (six sides of closed pore formula
Shape)), its generation and the peripheral sealing of skin closure formula hinder sweat across the lateral transfer of skin surface, but allow sweat from
Conveying of the sweat duct to film 916.In other words, adhesive includes the volume of multiple laterally closures, and this will further be begged for below
By.Another embodiment of the invention can include the adhesive in continuous film, and it is defeated for sweat or biomarker
It is impermeable enough to send, but is optionally ruptured above sweat duct due to sweat pressure, therefore partly makes life
Thing mark is transmitted by it.In this respect, adhesive can include the rupturable element that can be ruptured.Rupturable element can be with
It is inviscid thin and fragile solid film, therefore it also serves as the part of pressure permeation.Furthermore, it is possible to (to body) applies outer
Portion's malleation or negative pressure, to realize or strengthen the activation that sweat or biomarker only above sweat duct are conveyed.This area is general
Lead to it will be recognized that other materials or construction can generate such state:With it is outside sweat duct or basic at it
The conveying of outside skin area is compared, and the state is more beneficial for the defeated of the solute at neighbouring sweat duct or above sweat duct
Send.
With reference to Figure 10, device 1000 includes that sensor 1020, microfluidic components 1030, substrate 1010 and sweat stimulate machine
Structure.Sweat stimulates holder of the mechanism including sweat stimulating electrode 1050 and sweat stimulant 1040.In the illustrated embodiment,
Sweat stimulation is limited to or is conducive to only allowing to be connected 1056 region with the fluid or iontophoresis of sweat duct 14 in element 1005.
Element 1005 is unfavorable for conveying 1058.When this is conducive to localization sweat to stimulate and reduce potential adverse side effect or reduce long
Between the excitant that stimulates of sweat or reduce short-term stimulation to the people with sensitive skin.Additionally, this is for for example in individuality
It will be particularly advantageous that back stimulates sweat, wherein individual back sweat gland density is relatively low, and skin smaller portions area meeting
It is stimulated and it is therefore possible to irritant.Therefore, the sweat volume of reduction not only contributes to the sampling interval, and in sweat thorn
Sharp aspect is also useful.Although not shown, even if it is indirectly, such as urging the perspiration of the axon reflex of sweat that sweat stimulates
Situation, sweat stimulates can also benefit from the sweat volume of reduction.An embodiment of the invention is included by diffusion sweat
The sweat of liquid stimulant stimulates (i.e., it is not necessary to for the electric field of iontophoresis).
With reference to Figure 11, device 1100 includes the sensor 1120 and electrode 1170 in microfluidic components or gel 1130, its
With iontophoresis or electrically (electrosmotically) extracts the solute from body from sweat duct 14 (lead 1166).
The fluid favourable in the top of sweat duct 14 realized by element 1105 or conveying connection 1158 so that be conducive to from sweat duct 14
Rather than conveying 1168 in extract solute.In some cases, this can be provided for example to the solute in the blood for expecting measurement
Favourable path is (for example, in some cases, sweat duct provides shorter or more conductive defeated between blood and body outside
Send path).It will be appreciated by those of ordinary skill in the art that the sweat shown in Figure 10 and 11 stimulates and solute extraction can also group
Close, and material arranged/layer as needed, enable to realize the performance of application-specific.Substrate 1110 can for example be helped
For device provides physical stability.In one aspect of the invention, the sweat volume of reduction be also beneficial to include by diffusion, from
Sub- electric osmose, the solute flowing of electroendosmosis are collected, without only due to the solute flowing or collection of convective flow.
With reference to Figure 12, device 1200 includes the second element 1215, and it can be in one or more functions similar to element
1205 (for example, the element 905 of Fig. 9 or other the suitable methods such as instructed herein).Element 1215 is placed on sensor 1220
Top and covered by gel 1232.For example, device 1200 can include impedance spectrum sensor or amperometric sensor, and
Sensor electrode can be supported with neighbouring element 1205,1215 or by element 1205,1215.The advantage of device 1200 includes following:
Mitigate reverse diffusion of the solute from gel 1232;Mitigate the pollution that skin solute is caused;And substantially reduce required fluid volume
Or stream.Some or all in these exemplary advantages can be very beneficial for sweat sensing application, including expect minimum sweat
Those applications for stimulating.In an alternative embodiment, can not exist element 1205, and sensor 1220 can be with proximate skin
Place.In one embodiment, thin adhesive can be set between sensor and skin.
With reference to Figure 13 A, sweat sensing device further 1300 includes adhesive 1310, and adhesive 1310 includes carrier, is shown as including
The burst microcapsules 1385 of barrier material.For convenience, element 1301 schematically shows the different parts of device 1300.
In one implementation method, for example, element 1301 represents sensor and microfluidic components.Barrier material for example can be to intercept polymerization
Solution of the thing in suitable solvent.When device 1300 is applied on skin 12 securely, microcapsules 1385 rupture and skin
12 are coated with barrier material.At this point, barrier material and carrier 1385 are the parts of device 1300, and with device 1300
Miscellaneous part simultaneously put on skin.Element 1310 can be porous so that sweat can flow through element 1310 with first
Part 1301 is sensed.The porous or fluid path that sweat enters element 1310 for example can so keep:By with sweat pipe
14 similar diameters it is porous, with cause hole be not blocked polymeric seal.Solvent in barrier polymer disappears over time
It is scattered in skin 12 or environment, produces Obstruct membrane 1386 as shown in Figure 13 B.Barrier material can also be it is solvent-free, can be with
Solidified by the change of pH value, or oxygen or other stimulants or change can be passed through when barrier material is applied into skin
The presence of material is learned to solidify.Adhesive 1310 can be included or carried in its surface extra with curing agent or other materials
The microcapsules of material, in crushing or rupture, the curing agent or other materials cause barrier material to solidify.Initially it is loaded into micro- glue
The adhesive of capsule can also be applied in combination with other side of the invention.
In another embodiment, barrier material can be the solid dry film or material for being located at the top of adhesive 1310.
Skin 12 can be prepared and be cleaned using solvent, the solvent cleaning skin and be barrier material solvent.Then will dress
Put 1300 to be placed on skin 12, barrier material is contacted with solvent on skin 12 so that barrier material dissolves and is coated in skin
Skin surface.Barrier material film 1386 is dried as solvent is dissipated in skin 12 or environment, is produced similar to shown in Figure 13 B
Construction.Many alcohol can be used for skin cleaning, and can utilize those alcohol having compared with low vapor pressure, and it applies the phase in paster
Between can by solvent keep in skin or on skin.
In another aspect of this invention, device can also include that the selectivity for only conveying solute of concern (such as ammonia) is defeated
Send element.The polymeric layer that can be adulterated using ammonium ion carrier in illustrative embodiments.In this case, delivery element
Selection characteristic will prevent in addition to ammonia from skin possibility reduction sensor performance solute.
In another aspect of this invention, adhesive can also change the characteristic of the top layer of skin so that skin becomes in itself
It is not easy to convey solute.This is occurred over just in the region of adhesive contact skin, therefore prevents the place (example without skin
Such as, the opening of sweat duct) conveying change.In one embodiment, what adhesive can have in a solvent is very low
The phase of the sealed polymer of molecular weight, the solvent penetrates into skin and is substantially sealed against in addition to sweat duct top.This
The example for planting adhesive includes but is not limited to the barrier polymer of the product similar to Smith and Nephew SKIN-PREP
Preparation, and provided in " performance evaluation of film forming barrier (skin sealants) " by the Lutz of of 3M companies, herein by
With reference to introducing.
With reference to Figure 14, device 1400 includes adhesive 1470 and pressure permeation part 1460, and they produce reduction body together
Long-pending path 1480.For example, adhesive 1470 can be foregoing hexagon or other closed pore formula patterns.On structure and
Composition, this construction can also be referred to as having main vertical porous network.Therefore, because the path 1480 that volume reduces,
Sensor 1420 will quickly receive sweat than other manner.The path 1480 that volume reduces can be with other aspects of the present invention
Combination is with further for device 1400 reduces sweat volume.
With reference to Figure 15, device 1500 includes sensor 1520, and further includes that material 1570 and optional pressure ooze
Saturating part 1560, it allows sweat to be hung down from skin compared with laterally being flowed (that is, parallel to skin surface) in sweat
It is straight to flow and produce the volume path 1580 for reducing more quickly with leaving.Pressure permeation part 1560 may be present in of the invention
In such implementation method, wherein material 1570 itself can not suitably reduce sweat volume.In one embodiment, material
1570 is adhesive.
In the alternate embodiments of device 1500, not including optional pressure permeation part.In such implementation method
In, including most of materials of adhesive can be significantly impermeable to sweat, and adhesive to sweat equipped with having porous
The pipe of property, hole or microfibre, and the flow path for being provided be mainly it is vertical.In other words, adhesive will be with vertical
(that is, compared with horizontal feed, adhesive is more beneficial for the vertical of the solute in sweat or sweat in anisotropic sweat path
Conveying), it can also be referred to as main vertical porous network.This adhesive can for example by being formed with vertical orientated
Flexible pipe, hole or microfibre thick adhesive, adhesive is then cut into relatively thin layer and is made.Adhesive is cut into layer will
Substantially expose pipe or the hole on adhesive either side.Optionally, adhesive can be by forming the porous or solubility of upright opening
Particle is made.For example, may be separated during the solidification of adhesive, first is mutually adhesive, and second is mutually volatility
Fluid, wherein volatile fluid form main vertical orientated hole when being escaped from adhesive during curing.Hole can also machinery
Ground is formed, such as with microneedle described adhesive producing hole before adhesive is used on skin.Or, hole or wicking are fine
Dimension can in adhesive random orientation, and with the length suitable with the thickness of adhesive so that some can be provided vertically
Porous path, and those of transverse direction will not be provided because they substantially terminate in it is substantially impermeable to sweat viscous
Inside mixture.The density of the vertical channel of sweat should be more than the density of sweat duct, so as to realize above-mentioned benefit, and make enough
The sweat of amount reaches device with sensed.
Useful adhesive can have several formulations in embodiments of the invention.For example, adhesive can be with
It is hydrogel, acrylate, hydrocolloid or a kind of adhesive of medical.Many adhesive formulations may be adapted to use hydrocolloid
The component and chemical substance of dressing and adhesive, its can be optimised for it is highly porous to sweat, gas, microorganism, oil etc. or
It is highly non-porous.This adhesive can also be buffered with antiseptic, oil suction bead, pH or maintain bead, or other can improve sweat
The long-term reliability of liquid sensing device further and the material of wearability are used together.Adhesive is in itself or due to can also containing sweat
It is conductive so that the solute conveying that it can be used in the sampling solute of device of the invention or iontophoretic delivery.
During the adhesive or other materials of perpendicular magnetic anisotropy can be used for embodiments of the present invention in the sweat fluid, its
There can be various constructions.For example, adhesive can include the filament with main vertical-path or hole, such filament or hole pair
In sweat it is porous and/or dissolves in sweat.In one embodiment, by hanging down that water-soluble polyethylene pyrrolidones is made
Fibers straight array can be produced similar to Velcro (Velcro) by using water-soluble polyethylene pyrrolidones as polymer
It is prepared by the structure of hasp.Then can have in the insertion of the surface of this similar Velcro can not significantly ooze to sweat
Saturating adhesive or gel.When device is placed on skin, sweat, by polyethylene dissolving pyrrolidones, is that sweat forms reduction
The path of volume.
In one aspect of the invention, the sweat volume of reduction can improve sweat sampling rate.In some cases, make
It is not enough to minimize sweat volume come bringing device with the method for such as bandage.In fact, little wearable technology needs to subtract
The volume of small such as sweat volume of the invention, therefore this needs are completely or significantly unique for the present invention.Device can
To keep being clamped to skin under stress to reduce sweat volume, but in simple paster or other wearable devices, deposit
Make the other manner of sweat volume minimization.In one aspect of the invention, adhesive can be curable.With can consolidate
The device of the adhesive of change is along being enough to be applied to the external pressure that device presses against skin on skin.External pressure can lead to
Cross such as fixture, rubber strip or miscellaneous equipment is provided.Then, adhesive can solidify so that be glued after external pressure removal
Mixture can retain the sweat volume of major part (if not all) reduction that the external pressure by applying is produced.With this side
Formula, the sweat volume of reduction will improve sweat sampling rate.Equipment for bringing device can also stimulate comprising delivering solidification
Element (such as heating element heater or ultraviolet LED array).Before bringing device, catalyst can be immersed in skin, bringing device
Afterwards, while maintaining sufficiently long pressure to support appropriate solidification, catalyst solidifies adhesive.In an implementation method
In, the microcapsules that adhesive in itself can be containing curing agent or other materials, it causes adhesive to solidify in crushing or rupture.
Various curable adhesives can be used in embodiments of the present invention.Adhesive can by light, heat, pH value,
Material in catalyst, skin or on skin or other such as distribute the mode of solvent from the adhesive of liquid or gel state
In at least one be applied in dry skin to solidify.Curable adhesive can be combined with other side of the invention to be made
With.In one embodiment, adhesive can include bead or particle, and bead and particle will reduce the sweat inside adhesive
Volume.
Figure 16 shows at least one of top view of the device 1600 of embodiments of the present invention.Adhesive 1670 leads to
Cross the path for producing multiple closed volume 1680 as described above to produce volume to reduce.When device 1600 is placed on skin 12
When, some closed volumes 1680 will be alignd on sweat duct 14, and other are not lined up then.Closed volume 1680 on sweat duct 14
Will form mean for the path that the volume of sweat reduces.In addition, the closed volume 1680 not on sweat duct 14 will not be for sweat
The part in the path that the volume of liquid reduces.Device 1600 also includes microfluidic components 1665, to allow from may provide sweat
Any closed volume 1680 sweat collection.In this respect, there is the network of closed housing of microfluid connection in device 1600
In provide reduce sweat volume and reduce sweat path.Microfluidic components 1665 can be by sweat from closed volume
The 1680 any microfluidic pathways or material that one or more sensor (not shown) are transported to along the direction of shown arrow.In order to
Further each closed volume 1680 is isolated from each other, the branch of microfluidic components can include towards sensor by for example pressing
Unidirectional or pressure permeation the flow valve that power break is formed.Multiple unidirectional or pressure permeation flow valves are those skilled in the art
It is known.Implementation method as shown in Figure 16 A, the one-way flow valves of pressure permeation are for the bar or barrier in microfluidic components 1665
Hinder thing 1668, it causes the sweat pressure of the reduction compared with the diameter without such bar or the sweat stream of barrier 1668 to ooze
Saturating 1666 diameter (that is, barrier 1668 shows as pressure permeation part).Although microfluidic components 1665 are particularly shown
It is to include barrier 1668, but will readily appreciate that, in an alternative embodiment, such barrier can not be included.One
In individual implementation method, sweat solute can be with sufficiently low along the diffusion of the branch of microfluidic components so that even if all of obturator
Full of sweat, sweat volume also reduces.
With reference to Figure 17, device 1700 includes one group of sensor 1721,1722,1723,1724, and volume reduces part 1770,
The path 1780 that film or net 1760 and volume reduce.Although it is not shown, may further include such as sweat stimulates gel
Sweat stimulation elements and driving electrodes.As shown in lead 1755, at least one sensor 1724 can have for coming from skin
12 and sweat duct 14 sweat the path 1780 that reduces of the volume placed in the middle relative to sensor, which reduce the sampling interval.Tool
The path for having the volume placed in the middle relative to sensor to reduce is favourable, because if sweat stream is not placed in the middle, then sensing
A part for device is by with uneven and more slowly stream.Especially, the sweat stream near at least first area will be than passing
The fluid at other regions below sensor is slower.This slow sweat stream will cause old sweat to be tested together with new sweat
Amount, this will effectively increase the sampling interval.Therefore, the sensor being placed on skin 12 is small in any case, or no matter is passing
How many sweat volume between sensor and sweat duct reduces, and can receive sweat not placed in the middle under biosensor sensing surface
Liquid fluid.Present invention contemplates many sides for realizing the path that the volume in such as path 1780 placed in the middle relative to sensor reduces
Method.For the sensor with border circular areas, the stream at flow sensor center reading while by old sweat and new sweat
Mixing minimum aspect will be optimal.Although term " placed in the middle " may be not properly suited for the biography with non-circular geometry
Sensor, but aspect of the invention include it is optimal or close to the sensor structure that sweat is received in the way of optimum sampling interral to cause
Make.For example, in an embodiment of the invention, device can include that at least one sensor and at least one volume reduce
Path, wherein volume reduce path have for sensor quick sampling be spaced flow pattern.In other words, volume
The path of reduction includes the predefined paths through sensor of sweat, which reduces the sampling interval.It should be appreciated that can use
Various methods come constructing apparatus 1700 and similar implementation method.As an example, in other methods, it is possible to use the alignment of film
Lamination or photoetching carry out constructing apparatus 1700.
At one of the invention favourable aspect, sensor can be porous for sweat.Including the biography porous to sweat
Sensor can reduce new sweat and old sweat is washed away into the required time from sensor.In addition, if sensor is porous,
Then sweat stream will be placed in the middle or uniform (therefore " fluid placed in the middle " can also include " homogeneous (uniform) fluid ") by sensor.Porous biography
Benefit can also be expanded to other embodiments of the present invention by sensor, even the sensor without placed in the middle or uniform stream.
In one aspect of the invention, sensor can be coated with and make material soaked with sweat, to improve wetting of the sweat to sensor
Property.Some sensors are hydrophobic on the surface that it will be soaked by sweat or are at least insufficient to hydrophilic.Generally, yarn fabric,
Paper or microfluidic components or feature can be placed with proximity sensor so that sensor surface is arrived in fluid wicking and wetting.However, appointing
What such additional components all significantly increases sweat volume, when being especially considering that the thickness of yarn fabric or paper part.With reference to
Figure 17 A, in an embodiment of the invention, sensor 1721,1722,1723 is coated with hydrophilic towards the surface of skin 12
Or super-hydrophilic coating 1790.Sensor coatings for example can be directly placed on sensor surface polyvinylpyrrolidone,
Wicking nanofiber or other materials.For example, sensor coatings can use the dilute solution in water, ethanol to spray, use
Surfactant is improving wetting of the coating to sensor surface, or does not use surfactant.In dried forms, this coating
Can be from several thickness in monolayer to micron thickness or bigger, and still realize that desired sweat moistens through sensor surface
It is wet.Compared with conventional method, the path that coating provides the sweat volume or volume reduction for reducing is made soaked with sweat on sensor.
With reference to embodiments of the present invention, it has been shown that adhesive, bead layer or further feature or material, it is used for
Contact on skin, other on particle, hair, mole or the skin for not having increase sweat volume on skin in the contact are special
Levy.The present invention also includes the modification to implementation method of the problem for being used to cover such as skin smooth, or including such as compared with thick-layer
Or the device modification of adhesive.
Following examples are provided to help to illustrate the present invention, and these embodiments are not comprehensive or never in any form
The limitation present invention.
Embodiment 1
Low rate of perspiration or target solute the extraction region realized by the present invention can also allow for the sensing to some solutes,
The sensing is otherwise probably difficult.For example, big rate of perspiration can cause sweat gland to produce a large amount of lactic acid in itself so that can not survey
Amount blood lactic acid.Embodiments of the present invention can allow the blood lactic acid for being assigned to sweat duct or sweat gland to exceed by sweat gland generation
Lactic acid, therefore, it is possible to improve to the measurement by sweat duct or sweat gland lactic acid.Similarly, large-size or lipophilicity sweat are molten
Matter may be very slowly diffused into sweat, it is necessary in low-down rate of perspiration down-sampling, associated with blood with providing, because
The sweat volume of this reduction of the invention has significant value.The embodiment further illustrates sweat volume of the invention to be had
Value more than sampling interval only.
Embodiment 2
Calculated, to determine in 140 sweat gland s/cm2On the exemplary sweat sampling sites of (for example, belly)
And the sweat of per minute 0.5 and 5nL produces speed, the sampling interval of sweat sensing device further.Use simple volume fill mould
Type, the sensor of the 2.5mm diameters with 30 μm of the mean gap with skin surface for 5 and 0.5nL/min/ sweat glands feelings
Condition will respectively provide the sampling interval of 42.9 and 4.3 minutes.The sweat volume that the embodiment does not reduce.
Embodiment 3
Using identical sampling sites characteristic and size sensor, to wherein use petroleum jelly cream filling sensor and skin it
Between the embodiment of sweat volume calculated.Assuming that the sweat volume between sensor and petroleum jelly cream is negligible
(for example, pressure permeation part can be between sensor and petroleum jelly cream).Obtained in the case of 0.5nL/min/ sweat glands
Sampling interval is less than 1 minute.Even if having as low as 10 μm of space between sensor and pressure permeation part, ratio is also provided
3 times of sampling interval is improved in embodiment 2.
Embodiment 4
Using identical sampling sites characteristic and size sensor, the hexagonal close chamber on skin is included to wherein device
The embodiment of the adhesive of volume mesh is calculated.Assuming that adhesive height is 30 μm, width of adhesive is 3:1 aspect ratio
(that is, 90 μm of width), then a diameter of 360 μm of the adhesive of 80% aperture area.In the case of 0.5nL/min/ sweat glands
The gained sampling interval is less than 4 minutes.At this point, though between sensor and pressure permeation part Existential Space, sweat volume
At least a portion be also significantly reduced.
Embodiment 5
Using sampling sites characteristic same as Example 4 and size sensor, the hydrophobic of random polymerization is included to device
The embodiment of bead is calculated.The sampling interval obtained in the case of 0.5nL/min/ sweat glands is less than 1 minute.This point
On, even if the Existential Space between sensor and pressure permeation part, at least a portion of sweat volume has also been significantly reduced.
Claims (27)
1. it is used to be sensed on skin the perspiration sensor device of sweat, including:
One or more perspiration sensors;And
Volume reduces part, and when described device is located on the skin, it is in one or more biographies that the volume reduces part
Sweat between sensor and sweat gland provides the path that volume reduces;
Wherein described volume reduces part and selects free volume to reduce material and pressure permeation part, sweat soluble material, be used for
Comply with the mechanical compliant materials on the surface of the skin, the adhesive in the sweat path with perpendicular magnetic anisotropy, including intercepting
The microcapsules of material, and combinations thereof composition group.
2. device according to claim 1, wherein the volume reduces part includes that volume reduces material, pressure permeation portion
Part and sweat soluble material.
3. device according to claim 1, wherein the volume reduces part includes multiple closed volumes.
4. device according to claim 3, wherein miniflow of the multiple closed volume for the sweat volume of closed housing
Body connects network.
5. device according to claim 1, wherein the volume reduces part includes curable adhesive.
6. device according to claim 1, wherein the volume reduces part includes sweat soluble material.
7. device according to claim 6, wherein the sweat soluble material is microporous.
8. device according to claim 6, wherein the sweat soluble material includes promoting the feature of sweat wetting.
9. device according to claim 1, wherein the volume reduces the surface that part includes for complying with the skin
Mechanical compliant materials, the mechanical compliant materials include multiple beads.
10. device according to claim 9, wherein at least a portion of the bead is hydrophilic.
11. devices according to claim 9, wherein at least a portion of the bead is hydrophobic.
12. devices according to claim 9, wherein at least a portion of the bead is oiliness.
13. devices according to claim 9, wherein at least a portion of the bead can not ooze including transferable sweat
Antireflective coating layer.
14. devices according to claim 9, wherein at least a portion of the bead includes adhesive coating.
15. devices according to claim 9, wherein at least a portion of the bead has at least one magnetic properties.
16. devices according to claim 1, wherein the volume reduces part includes the sweat with perpendicular magnetic anisotropy
The adhesive in path.
17. devices according to claim 1, wherein described adhesive include main vertical porous network.
18. devices according to claim 1, wherein the volume reduces part includes the microcapsules of barrier material,
When described device is applied on skin, the microcapsules discharge the barrier material to form obstruct on the skin
Thing.
19. devices according to claim 1, including sweat stimulates part.
20. devices according to claim 19, wherein the sweat stimulates the path that part reduces including the second volume, when
Described device is located at when on the skin, and the path that second volume reduces stimulates between part and sweat gland in sweat;And
The path that wherein described volume reduces is by volume reduction material and pressure permeation part, sweat soluble material, for suitable
Answer the mechanical compliant materials on the surface of the skin, the adhesive in the sweat path with perpendicular magnetic anisotropy, including intercepting material
One or more features in the microcapsules of material, bead, multiple horizontal closed volumes and combinations thereof the group of composition are limited.
21. devices according to claim 1, wherein when described device is located on the skin, the volume reduction portion
Part provides the path of volume reduction for the sweat between one or more of perspiration sensors and sweat gland, and the volume reduces
Path include:
For the predetermined path of the sweat through the sensor;And
Wherein one or more sensors have the sampling interval when sweat is sensed, and the path that the volume reduces reduces institute
State the sampling interval of one or more sensors.
22. devices according to claim 21, wherein the stream of the sweat from the skin is in one or more of sweat
It is placed in the middle in liquid sensor.
23. perspiration sensor devices, including:
One or more perspiration sensors;And
Volume reduces part, and when described device is located on the skin, it is one or many that the volume reduces part
Sweat between individual sensor and sweat gland provides the path that volume reduces, and the path that the volume reduces is included being used for through described
The predetermined path of the sweat of sensor;
Wherein one or more sensors have the sampling interval when sweat is sensed, and the path that the volume reduces reduces institute
State the sampling interval of one or more sensors.
24. devices according to claim 23, wherein the sweat stream from the skin is one or more of
It is placed in the middle in perspiration sensor.
25. perspiration sensor devices, including:
One or more perspiration sensors;
Volume reduces part, and when described device is located on the skin, it is one or many that the volume reduces part
Sweat between individual sensor and sweat gland provides the path that volume reduces, and the path that the volume reduces is included being used for through described
The predetermined path of the sweat of sensor;And
Sweat wet material coating on one or more perspiration sensors.
26. perspiration sensor devices, including:
One or more perspiration sensors;And
Volume reduces part, and when described device is located on the skin, it is one or many that the volume reduces part
Sweat between individual sensor and sweat gland provides the path that volume reduces, and the path that the volume reduces is included being used for through described
The predetermined path of the sweat of sensor;
Wherein described volume reduces part includes the volume of multiple closings.
27. devices according to claim 26, wherein the volume of the multiple closing is the sweat volume of closed housing
Microfluid connects network.
Applications Claiming Priority (13)
Application Number | Priority Date | Filing Date | Title |
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US201462003715P | 2014-05-28 | 2014-05-28 | |
US201462003675P | 2014-05-28 | 2014-05-28 | |
US201462003692P | 2014-05-28 | 2014-05-28 | |
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CN106793969A true CN106793969A (en) | 2017-05-31 |
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CN201580039933.4A Pending CN106793969A (en) | 2014-05-28 | 2015-05-28 | The device of the sweat volume with the reduction between sensor and sweat gland |
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US (1) | US10639015B2 (en) |
EP (1) | EP3148416B8 (en) |
JP (1) | JP2017522924A (en) |
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AU (1) | AU2015266956A1 (en) |
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WO (1) | WO2015184097A2 (en) |
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CA2950594A1 (en) | 2015-12-03 |
EP3148416A4 (en) | 2018-01-10 |
WO2015184097A2 (en) | 2015-12-03 |
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WO2015184097A3 (en) | 2016-01-21 |
EP3148416B8 (en) | 2024-04-17 |
US10639015B2 (en) | 2020-05-05 |
EP3148416B1 (en) | 2024-03-13 |
JP2017522924A (en) | 2017-08-17 |
AU2015266956A1 (en) | 2016-12-15 |
EP3148416A2 (en) | 2017-04-05 |
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